EP0385429A2

EP0385429A2 - Self-routing switching system having dual self-routing switch module network structure

Info

Publication number: EP0385429A2
Application number: EP90103881A
Authority: EP
Inventors: Osamu Isonoo; Toshimasa Fukui; Tetsuo Nishino; Tetsuo Tachibana; Ryuji Hyodo; Eisuke Iwabuchi
Original assignee: Fujitsu Ltd
Current assignee: Fujitsu Ltd
Priority date: 1989-03-01
Filing date: 1990-02-28
Publication date: 1990-09-05
Also published as: EP0385429A3; CA2011174C; US5072440A; CA2011174A1

Abstract

A self-routing switching system connected between input highways (10) and output highways (60), includes conversion modules (20), doubled SRM networks (30), output modules (50), and first and second selectors. Normally, one of the SRM networks is connected between the conversion modules and output modules through the first and second selectors. When a request to switch the active network to the other SRM network, the first and second selectors switch connections to the conversion modules and output modules so that the other SRM network is connected between the conversion modules and output modules. Before actually switching the connections, it is determined whether or not all cells have been discharged from the active SRM network.

Description

BACKGROUND OF THE INVENTION

The present invention generally relates to a self-routing switching system, and particularly to a self-routing switching system which is optimal for use for high-speed packet switching or asynchronous transfer mode (ATM) switching.
As is well known, a self-routing switch module network providing speech paths is suitable for cases of high-speed switching to different outgoing lines for each packet or each cell (asynchronous transfer mode blocks), such as high-speed packet switching or asynchronous transfer mode switching, and for cases where centralized control of the speech path by software is not desired because of the need for high speed call processing.
Conventional self-routing systems have been proposed in, for example: The 6the Annual Symposium on Computer Architecture, 23-25 April 1979, IEEE, (New York, US), T.-Y. Feng et al.: "A microprocessor controlled asynchronous circuit switching network", pages 202-215; IEEE Journal on Selected Areas in Communications, volume SAC-4, no. 8, November 1986, IEEE (New York, US), J.S. Turner: "Design of an integrated services Packet network", pages 1373-1380; International Journal of Electronics, volume 56, no. 6, June 1984, (Basingstoke, Hampshire, GB), S.K. Paranjpe et al.: "A new concept for supermodular alignment network", pages 815-822; IEEE Transactions on Computer, volume C-34, no. 2, February 1985, IEEE, (New York, US), M. Kumar et al.: "Switching strategies in shuffle-exchange Packet-switched networks", pages 180-186; Journal of the Institution of Electronic and Radio Engineers, volume 56, no. 6/7, June/July 1986, IEEE, (London, GB), M. Nagasawa et al.: "Packet switching network access protocols for multi-media packet communications", pages 243-247: European Patent Application No. 0113639 (SERVEL et al.) 18 July 1984; Proceedings of the 1981 International Conference on Parallel Processing, 25-28 August 1981, IEEE, (New York, US), R.J. McMillen et al.: "Performance and implementation of 4x4 switching nodes in an interconnection network for PASM", pages 229-233; British Application No. 904100 (ITT) 24 July 1986; European Patent Application No. 0206403 (RACAL) 30 December 1986; and United States Patent Application Serial Nos. 157,621, 198,089, 280,723 and 320,574.
However, none of the above-identified references disclose a self-routing switching system in which a self-routing switch module network is doubled.

SUMMARY OF THE INVENTION

It is a general object of the present invention to provide an improved self-routing switching system in which the self-routing switch module network is doubled so that reliability of the system is enhanced and maintenance operation is improved.
The above object of the present invention is achieved by A self-routing switching system connected between input highways and output highways, comprising input means coupled to the input highways, for receiving a cell having transmission information from one of the input highways and for generating additive information indicative of a path through which the transmission information from the one of the input highways is supplied to one of the output highways; first self-routing switch module network means for providing a plurality of paths operatively coupled between the input highways and output highways, the cell being transmitted through one of the plurality of paths indicated by the additive information; second self-routing switch module network means for providing a plurality of paths operatively coupled between the input highways and output highways, the cell being transmitted through one of the plurality of paths indicated by the additive information; first selecting means, provided between the input means and the first and second self-routing switch module network means, for connecting the input highways to one of the first and second self-routing switch module network means; and second selecting means, provided between the input means and the first and second self-routing switch module network means, for connecting the output lines to one of the first and second self-routing switch module network means.
Another object of the present invention is to provide a self-routing switching system having doubled self-routing switch module networks which is capable of preventing information from being lost when one of the doubled self-routing switch module networks is switched to the other one.
This object of the present invention is achieved by providing the above-mentioned system with detecting means operatively coupled to the first and second self-routing switch module network means, for detecting a state where there is no cell in the one of the first and second self-routing means selected by the first selecting means, the one of the first and second self-routing means functioning as an active network and the the other one thereof functioning as a standby network. The first and second selecting means switch connections to the input and output lines from the active network to the standby network when the detecting means detects the state.
Further objects, features and advantages of the present invention will become apparent from the following detailed description when read in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG.1 is a block diagram of the entire structure of a self-routing switching system having a doubled self-routing switch module network structure according to the present invention;
FIG.2 is a block diagram how to switch the system from an active self-routing switch module network to a standby one according to the first embodiment of the present invention;
FIG.3 is a diagram showing a virtual call number (VCN) conversion table provided in a conversion module in the system shown in FIG.1;
FIG.4 is a block diagram of a second preferred embodiment of the present invention;
FIG.5 is a block diagram of a conversion module (input module) provided in the configuration shown in FIG.4;
FIG.6 is a block diagram illustrating a format of a discharge confirmation cell used in the second embodiment shown in FIG.4;
FIG.7 is a block diagram of an output module provided in the configuration shown in FIG.4;
FIG.8 is a diagram showing how to manage a call by a central processing unit used in the second embodiment shown in FIG.4;
FIG.9 is a block diagram how to switch the network from an active self-routing switch module network to a standby one according to the second embodiment shown in FIG.4;
FIG.10 is a block diagram of a third preferred embodiment of the present invention;
FIG.11 is a block diagram of a conversion module provided in the third embodiment shown in FIG.10;
FIG.12 is a block diagram of a general configuration of a self-routing switch module network used in each of the first to third embodiments;
FIG.13 is a block diagram of a self-routing module provided specifically for the third embodiment shown in FIG.10;
FIG.14 is a block diagram illustrating how to collect signals from AND gates provided for the self-routing modules according to the third embodiment of the present invention;
FIG.15 is a block diagram of a configuration of an output module provided in the third embodiment shown in FIG.10; and
FIG.16 is a block diagram how to switch the system from an active self-routing switch module network to a standby one according to the third embodiment shown in FIG.10.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A description is given of a self-routing switching system according to a first preferred embodiment of the present invention with reference to FIG.1. The self-routing switching system shown in FIG.1 is composed of conversion modules 20, a pair of doubled self-routing switch networks (hereinafter referred to SRM networks) 30 and 40 such as ATM switch networks, output modules 50 and a central processing unit (CPU) 70. Input highways (links) 10 are individually accommodated by the conversion modules 20. The conversion modules 20 are connected to the input ends of the SRM networks 30 and 40. Normally, one of the SRM networks 30 and 40 functions as an active network, and the other SRM network functions as a standby (reserved) network. The output modules 50 are connected to the output ends of the SRM networks 30 and 40. Output highways (links) 60 are individually connected to the output modules 50. The CPU 70 functions as a call processor and controls the conversion modules 20 and the output modules 50.
A description is given of the operation of the system shown in FIG.1 with reference to FIGS.2 and 3. It is now assumed that the SRM network 30 serves as the active network, and the SRM network 40 serves as the standby system. It is noted that in FIG.2, one of the conversion modules 20 and one of the output modules 50 are illustrated for the sake of simplicity. An input cell on the input highway 10 is applied to the conversion module 20. As is known, an input cell on the input highway 10 is composed of a header and transmission information INF. The header includes a virtual call number VCN₀ of the input cell (identification information: "a" in the illustration) and a synchronizing pattern. The conversion module 20 refers to a VCN conversion table (FIG.3) provided therein, and gets information about a route number (control information: this corresponds to a set of route headers described later) indicating a set of speech paths (lines) formed in the SRM network 30 on the basis of the virtual call number VCN₀ ("a") of the input cell, and a virtual call number VCN₁ ("b" in the illustration) for a next link through which the cell is transmitted to a subsequent self-routing switching network or a terminal. The route number and the virtual call number VCN₁ ("b") for the next link are provided by call by call in the VCN conversion table shown in FIG.3 by the CPU 70. Then the conversion module 20 sends the input cell having information INF and the virtual call number VCN₁ ("b") to the active SRM network 30. As will be described in detail later, each of the SRM networks 30 and 40 includes a plurality of stages each having a plurality of SRM modules (see FIG.12). The SRM modules at the different stages are connected to lines or paths. The cell input to the conversion module 20 is transmitted in a route of lines connecting the different stages and is then supplied to the output module 50. The cell from the output module 50 is sent to the output highway 60 through the output module 50. The above-mentioned procedure is indicated by P1 (FIG.2).
Before the active SRM network is actually switched from the SRM network 30 to the SRM network 40, input cells on the input highway 10 are temporarily stored in a queuing buffer provided in the conversion module 20. This procedure is indicated by P2. On the other hand, all cells in the SRM network 30 must be completely discharged to the output module 50 as indicated by P3 before the active SRM network is actually switched to the SRM network 40. For this purpose, the CPU 70 starts an internal timer when a change of the active SRM network is requested through an external device (not shown) such as a console connected to the CPU 70. The CPU 70 always determines whether or not a predetermined time has passed. It is possible to know a time it takes to completely output all cells in the SRM network 30 beforehand, for example, at the stage of designing the system. The predetermined time is set equal or greater than such a time. When it is determined that the predetermined time has passed, as indicated by P4, the CPU 70 controls the conversion module 20 so as to output the buffered cells to the SRM network 40 and controls the output module 50 so as to receive cells from the SRM network 40. Then cells queued in the queuing buffer in the conversion module 20 are output to the SRM network 40 which is now changed to the active system, as indicated by P5. In this manner, the active network is switched from the SRM network 30 to the SRM network 40 after the predetermined time passes.
In order to achieve the state where all cells in the active SRM network have already been output to the output module 50 when a request to change the active SRM network is generated, it is necessary to provide a sufficient time interval between the occurrence of the request and actual switching. If the predetermined time is not sufficient, some of cells are left in the active SRM network and thus lost. Further, when a small number of cells is left on the output side of the active SRM module, it is not necessary to measure the entire predetermined time. The second embodiment of the present invention is directed to improving the first embodiment of the present invention.
The self-routing switching system according to the second embodiment of the present invention shown in FIG.4 is composed of a conversion module 120 and an output module 150, which are substituted for the conversion module 20 and the output module 50, respectively. The control operation of the CPU 70 shown in FIG.4 is different from that of the CPU 70 shown in FIG.1, as will be seen from the following description. The conversion module 120 includes a buffer 121 which temporarily stores input cells on the input highway 10, a discharge confirmation cell generator 122, and a selector 123. The output module 150 includes a selector 151, and a discharge confirmation cell detector 152. The system shown in FIG.4 includes the doubled SRM networks 30 and 40.
In the case where the SRM network 30 is working as the active system, input cells on the input highway 10 are once stored in the buffer 121 and are then output to the SRM network 30 through the selector 123, which is controlled by the CPU 70. Then the cells are output from the SRM network 30 and then transmitted to the output highway 60 through the selector 151 and the discharge confirmation cell detector 152 of the output module 150.
When a request to switch from the SRM network 30 to the SRM network 40 is input to the CPU 70 from a console (not shown in FIG.4), the CPU 70 instructs the discharge confirmation cell generator 122 to generate a discharge confirmation cell, and instructs the selector 123 to connect the discharge confirmation cell generator 122 to the SRM network 30. The discharge confirmation cell from the discharge confirmation cell generator 122 passes through the selector 123 and is input to the SRM network 30 which is working. The discharge confirmation cell passes through the SRM network 30 and is input to the discharge confirmation cell detector 152 through the selector 151 of the output module 150. The discharge confirmation cell detector 152 detects the discharge confirmation cell from the SRM network 30, and informs the CPU 70 of the fact of detection. When the discharge confirmation cell is detected, it can be determined that all cells left in the SRM network 30 when the request occurs have been output therefrom completely. Thus, the CPU 70 controls the selector 123 of the conversion module 120 so as to connect the buffer 121 and the SRM network 40, and controls the selector 151 of the output module 150 so as to select the SRM network 40. Thereby, a route of connecting the conversion module 120, the SRM network 40 and the output module 150 is established.
The self-routing switching system shown in FIG.4 can eliminate a problem of the system shown in FIG.1. It is noted that the system shown in FIG.1 has a possibility that some of cells in left in the active SRM network may be lost in case where the aforementioned predetermined time is insufficient. In other words, the system shown in FIG.4 does not have a means for determining whether or not all cells left in the active SRM network have actually been output.
Referring to FIG.5, there is illustrated a detailed configuration of the conversion module 120. The conversion module shown in FIG.5 is made up of a buffer 21a, a queuing buffer 21b, a selector 22, a synchronizing circuit 23, a register 24, a decoder 25, a selector 26, a VCN conversion table memory 27, a discharge confirmation cell generator 28, a register 28a and a selector 29. The configuration shown in FIG.5 is an improvement in a configuration disclosed in International Publication Number WO 88/05982, the disclosure of which is hereby incorporated by reference.
The discharge confirmation cell generator 28 generates the discharge confirmation cell having a format shown in FIG.6. As is shown, the discharge confirmation cell contains a discharge confirmation cell identifier illustrated by the hatched block, the virtual call number VCN₁ for the next link and transmission information INF. The discharge confirmation cell identifier is a one-bit flag. Normally, each cell has a definite length and contains some auxiliary (service) bits. One of the auxiliary bits is used for forming the discharge confirmation cell identifier. The position of the discharge confirmation cell identifier is not limited to the beginning of the cell. The virtual call number VCN₁ ("b") is read out from the VCN conversion table memory 27 according to the virtual call number VCN₀ ("a"). A reference CNVNo, which is contained in the transmission information INF, indicates the number of the conversion module 20, which is supplied from the register 28a.
As is shown in FIG.5, the VCN conversion table memory 27 has, for each call, an area 27a for storing a virtual call number VCN₀, an area 27b for storing a virtual call number VCN₁ for a next link, an area 27c for storing a route number, and an area 27d for storing data indicating whether or not the virtual call number VCN₁ for a related next link is in a communication state. When each virtual call number VCN₁ is in the communication state, a flag of "1" is stored in a corresponding portion of the area 27d. On the other hand, when each virtual call number VCN₁ is in a non-communication state, a flag of "0" is stored in a corresponding portion of the area 27d. The CPU 70 sets the flag in the area 27d for every call.
The buffer 21a stores cells transmitted from the input highway 10. The synchronizing circuit 23 synchronizes with each cell from the input highway 10 or the buffer 21b by using the aforementioned synchronizing pattern in the header thereof. The register 24 stores the virtual call number VCN₀ of the input cell ("a" in FIG.5) at a timing defined by the synchronizing circuit 23. The decoder 25 decodes the virtual call number VCN₀ of the input cell ("a") and generates a corresponding address of the VCN conversion table 27. The address from the decoder 25 passes through the selector 26, which is controlled by the synchronizing circuit 23. That is, each time a call is input to the synchronizing circuit 24, the selector 26 passes the address from the decoder 25. When the address corresponding to the virtual call number VCN₀ ("a") is input to the VCN conversion table memory 27, the corresponding virtual call number VCN ("b") of the cell in the next link and the route number are read out therefrom. The selector 22 is controlled by the CPU 70 so that the virtual call number VCN₁ ("b") and the route number are added to the corresponding cell which is read out from the buffer 21a or 21b. Thus, the selector 22 outputs the route number, the virtual call number VCN₁ and transmission information in this order. Normally, the selector 29 selects the active SRM network (the SRM network 30 for example). The output signal from the selector 22 is supplied to the SRM network 30 through the selector 29.
When a request to switch the active SRM network from the SRM network 30 to the SRM network 40 is input to the CPU 70 through a console 75 (FIG.5), the CPU 70 instructs the discharge confirmation cell generator 28 to read out, from the VCN conversion table memory 27, the virtual call number VCN₀ ("a") and a virtual call number VCN₁ ("b") which is in the communication state. Further, the CPU 70 instructs the discharge confirmation cell generator 28 to read out the number CVCNo of the conversion module 120 from the register 28a. Then the discharge confirmation cell generator 28 forms the discharge confirmation cell (illustrated by the hatched block) having the format shown in FIG.6. At the same time, the discharge confirmation cell generator 28 controls the selector 22 so as to select the discharge confirmation cell and controls the selector 29 to output the same to the SRM network 30, which is working as the active SRM network. Then the CPU 70 sets the flag to "0".
As will be described in detail later, when the output module 150 (FIG.7) detects the discharge confirmation cell and lets the CPU 70 know the fact of detection, the CPU 70 reads out the cells from the queuing buffer 21b (queuing cells) and supplies the same to the synchronizing circuit 23. Then the route number, the virtual call number VCN₁ ("b") and the transmission information are added to each of the cells from the synchronizing circuit 23 due to the function of the selector 22 in the same manner as described previously. When the CPU 70 is informed that the discharge confirmation cell is detected by the output module 150, the CPU 70 controls the selector 29 so as to select the SRM network 40, whereby it is now switched to the active network. The output signal from the selector 22 is supplied to the SRM network 40 through the selector 29.
Referring to FIG.7, there is illustrated a configuration of the output module 150. As is shown, the output module 150 is composed of a selector 51, a discharge confirmation cell detector 52, and a memory 53. The selector 51 selectively connects one of the SRM networks 30 and 40 to the discharge confirmation cell detector 52, which detects the discharge confirmation cell. As described previously, the discharge confirmation cell has the specific identifier placed, for example, at the beginning of the format thereof. The discharge confirmation cell detector 52 determines whether or not each received cell has the specific identifier, for example, at the beginning thereof. When detecting the discharge confirmation cell, the discharge confirmation cell detector 52 writes it into the memory 53. The CPU 70 determines whether or not the discharge confirmation cell detector 52 outputs an interrupt signal (switching signal) indicative of detection of the discharge confirmation cell. Alternatively, the CPU 70 periodically scans the memory 53, and determines whether or not there is the discharge confirmation cell in the memory 53. When the CPU 70 knows the fact that the discharge confirmation cell has been detected, the CPU 70 reads out the conversion module number CNVNo and the virtual call numbers VCN₀ and VCN₁ from the memory 53. Then the CPU 70 instructs the selector 29 (FIG.5) of the conversion module 120 to connect the selector 22 to the SRM network 40 and instructs the selector 22 to select the queuing buffer 21b. Further, the CPU 70 instructs the selector 51 (FIG.7) of the output module 150 to connect the SRM network 40 and the discharge confirmation cell detector 52.
FIGS.5 and 7 illustrate one of the conversion modules 120 and one of the output modules 150, respectively. In actuality, as shown in FIG.1, the self-routing switching system has a plurality of conversion modules each having the same structure as the conversion module 120, and a plurality of output modules each having the same structure as the output module 150. The plurality of conversion and output modules 120 and 150 are controlled by the CPU 70. In this case, the CPU 70 is required to detect discharge confirmation cells supplied from all the conversion modules 120 and then switch the active network.
For this requirement, the CPU 70 manages calls from the conversion modules 120 by using tables 71 and 72. The table 71 corresponds to the table shown in FIG.3. The table 72 is provided in the CPU 70, and has divided areas 73 and 74. The area 73 stores data indicating whether or not each virtual call number VCN₁ is in the communication state ("1" indicates the communication state, and "0" indicates the non-communication state). The area 74 stores data indicating whether each virtual call number VCN₁ is in a state where related cells are being discharged or in a state where all related cells have been discharged. When the conversion module number CNVNn (n is an integer) and the virtual call number VCN₀ are read out from the memory 53, the CPU 70 individually writes "0" into corresponding portions of the areas 73 and 74. When the CPU 70 detects the fact that "0" are written into all the portions of the area 74, the CPU 70 controls all the conversion and output modules 120 and 150 so as to select the standby SRM network.
A further description is given of the operation of the second embodiment with reference to FIG.9. The CPU 70 instructs the conversion module 120 to start the aforementioned procedure for switching the active SRM network (P1). In response to this instruction, the discharge confirmation cell generator 28 sends the discharge confirmation cell to the active SRM network 30 in the aforementioned procedure (P2). An input cell which is received after the discharge confirmation cell is sent to the SRM network 30, is stored in the queuing buffer 21b shown in FIG.5 (P3). The discharge confirmation cell detector 52 (FIG.7) of the output module 150 detects the discharge confirmation cell from the SRM network 30. The CPU 70 knows the fact of the detection of the discharge confirmation cell in the aforementioned manner (P4). Then the CPU 70 reads out, from the memory 53 (FIG.7), the conversion module number CNVNn and the virtual call number VCN₀ of the input cell contained in the received discharge confirmation cell (P5). When the CPU 70 is notified that the discharge confirmation cell from the conversion module 120 has been detected, it instructs the conversion module 120 to send the cells in the queuing buffer 21b to the SRM network 40. In actually, when the discharge confirmation cells have been detected, the CPU 70 instructs all the conversion modules including the conversion module 120 to send cells in the individual queuing buffers to the SRM network 40. Then the active SRM network 30 is switched to the standby network, and instead the standby SRM network 40 is made active.
A description is given of the self-routing switching network according to a third preferred embodiment of the present invention. Referring to FIG.10, there is illustrated an outline of the third embodiment. A conversion module 220 and an output module 250 are substituted for the conversion module 120 and the output module 150, respectively. The conversion module 220 includes a selector 221, which selectively connects the input highway 10 to either an SRM network 130 or the SRM network 40. The output module 250 includes a selector 251, which connects one of the SRM module 130 and the SRM network 40 to the output highway 60. The SRM network 130, which is provided instead of the SRM network 30, is configured by adding a detector 131 to the SRM network 30. The detector 131 determines whether or not there is any cell in the SRM network 130. Although a detector corresponding to the detector 131 is not provided for the SRM network 40, in actuality, it is preferable to provide the SRM network 40 with such a detector.
When the active SRM network 130 is working, each cell input to the conversion module 220 passes through the SRM network 130 and is supplied to the output module 250. When a request to change the active SRM network from the SRM network 130 to the SRM network 40 is input to the CPU 70, the CPU 70 instructs the selector 221 to connect the input highway 10 to the SRM network 40. Each cell addressed to the conversion module 220 is sequentially stored in the SRM network 40 from the input side thereof. It is noted that the SRM network 40 functions as a queuing buffer during the switching procedure. On the other hand, cells in the SRM network 130 are continuously discharged to the output modules 250. When the detector 131 detects the state where there is left no cell in the SRM network 130, the detector 131 notices the CPU 70 of the fact of detection. In response to the notice from the detector 131, the CPU 70 instructs the selector 251 to connect the output line 60 to the SRM network 40. Then cells stored in the SRM network 40 are sequentially read out therefrom and supplied to the output module 250.
It should be appreciated that cells input to the conversion module 220 after the request for switching is generated are queued in the SRM network 40. Thus, there is no need for providing the queuing buffer 21b (FIG.5) in the conversion module 220.
FIG.11 is a block diagram of the conversion module 220 shown in FIG.10, which corresponds to a conversion module disclosed in the aforementioned International Publication Number WO 88/05982. In FIG.11, those parts which are the same as those in FIG.5 are given the same reference numerals. The conversion module 220 includes a synchronizing circuit 23a and a selector 22a which are substituted for the synchronizing circuit 23 and the selector 22. As described previously, each cell on the transmission line is actually composed of the transmission information and the header added thereto. The transmission information includes identification information (VCN). In the conversion module 220, the route number (control information) is added to the cell.
The calling part of the packet information carries out a call setting up phase for notifying the packet receiving party to the CPU 70 before the transmission of the cell. The CPU 70 sets the path of the speech path through which the cell is to pass by the notified receiving party and calling party and decides a virtual call number for the next link. The switching information of the switch modules to which the packet is input, that is, the control information RH₁, RH₂ and RH₃ (corresponding to the aforementioned route number), and the virtual call number for the next link are stored in the address corresponding to the virtual call number VCN₀ which indicates the receiving party.
Next, the cell is actually transmitted in the cell transfer phase. This cell is composed of the transmission information and the header portion containing the virtual call number VCN₀ added to the header of the transmission information. The synchronizing circuit 23a synchronizes with the input cell for the use of a synchronizing pattern in the header portion, and controls the timing of each part. The cell which is transferred to the speech path is stored in the buffer 21a, and the virtual call number VCN₀ of the input cell is input to the decoder 25 via the register 24 under the control of the synchronizing circuit 23a. When the decoder 25 receives the virtual call number VCN₀ of the input cell, the VCN conversion memory 27 is accessed using this virtual call number VCN₀ as the address. The VCN conversion table memory 27 stores therein the control information (route number composed of route headers) corresponding to the virtual call number VCN₀ and the virtual call number (VCN₁) showing the cell in the next link. To add the control information and VCN₁ to the packet header, the control information read out from the VCN conversion table memory 27 is sent to the selector 22a. The synchronizing circuit 23a performs switching control of the selector 22a, first sends out the control information and new virtual call number VCN₁, then reads out the transmission information portion of the packet from the buffer 21a and sends it through the selector 22a. The signal from the selector 22a is transmitted to one of the SRM networks 130 and 40.
FIG.12 is a diagram of a configuration of the SRM network 130. The SRM network 40 also has a configuration identical to the illustrated configuration. FIG.12 relates to the case where there are three 3x3 self-routing switch modules SRM_ij at the input stage, middle stage and output stage. Primary links L₁₁, L₁₂ and L₁₃ connect the three output ends of the input stage switch module SRM₁₁ to the first top input ends of the middle stage switch modules SRM₂₁ to SRM₂₃. The primary links L₂₁ to L₂₃ and L₃₁ to L₃₃ follow this. The secondary links M₁₁ to M₁₃ connect the three output ends of the middle stage switch module SRM₂₁ to the first input ends of the three switch modules SRM₃₁ to SRM₃₃ of the output stage. The secondary links M₂₁ to M₂₃ and M₃₁ to M₃₃ follow the same.
Referring to FIG.13, there is illustrated a configuration of the SRM_ij shown in FIG.12. The SRM_ij is composed of control information detection circuits, I₁, I₂ and I₃, transmission information delay circuits D₁, D₂ and D₃, demultiplexers DM₁, DM₂ and DM₃, control information decode circuits DEC₁, DEC₂ and DEC₃, and buffer memories FM₁₁, FM₁₂, FM₁₃, FM₂₁, FM₂₂, FN₂₃, FM₃₁, FM₃₂ and FM₃₃. Each of the buffer memories FM_ij is formed by a first-in first-out (FIFO) memory. The SRM_ij is further composed of selectors SEL₁, SEL₂ and SEL₃, and selector control circuits SC₁, SC₂ and SC₃. The above-mentioned structural elements are also provided in the SRM network 40.
The signals entering the input ends #1 to #3 (i) take the form of the aforementioned transmission information plus control information. The detection circuits I_i (i = 3 in the illustrated case) extract the control information and send it to the decode circuits DEC_i. The control information comes in three types, a first stage (input stage) routing header RH1, a second stage (middle stage) routing header RH₂, and a third stage (output stage) routing header RH3, when the SRM network 140 is comprised of three stages, so the detection circuits I_i extract the corresponding control information according to which stages the switch modules SRM are. When the input control information indicates an output end j, a decode circuit DEC_i operates a demultiplexer DM_i and sends the transmission information to an FIFO memory FM_ji. For example, if the control information of the input end #1 indicates the output end #2, the decode circuit DEC₁ operates the demultiplexer DM₁ and inputs the information of the input end #1 to the FIFO memory FM₂₁. When the transmission information enters the FIFO memories FM₁₁ to FM₁₃, the selector control circuit SC1 operates the selector SEL₁ and sends the said transmission information to the output end #1. The same is true for the rest as well.
A selector control circuit SC_j, for example, continually scans for a request signal R_ij from an FIFO memory FM_ij and, when a request signal R_ij is detected, operates so that the contents of that FIFO memory FM are output through a selector SEL_i. Alternatively, a request signal R_ij is input to a selector control circuit SC_j as an interruption input and, when an interruption occurs, the selector control circuit SC_j outputs the content of the said FIFO memory FM through the selector SEL.
If the FIFO memories FM_ij are given a capacity corresponding to a plurality of cells, a buffer function is obtained and sufficient response is possible even when the transmission data increases temporarily.
The self-routing switch modules SRM_ij are not limited to ones having three input ends and three output ends and in general may have n number of input ends and m number of output ends, where n > m and n = m or n < m. When n > m, there will be a plurality of input ends making common use of the same output end, but with calls (channel) with small values of transmission, this would be sufficient for processing. When n < m, a single input may be divided into two outputs and both input side high speeds and output side low speeds dealt with. Of course, the excess amount may be left unused.
The above description with reference to FIG.13 holds true for the SRM network 40. As shown in FIG.13, an AND gate 31 is provided specifically for the SRM network 140. The AND gate 31 corresponds to the detector 131 shown in FIG.10. When a detector such as the detector 131 is provided for the SRM network, an AND gate is provided for the SRM network 40. Thereby, it is possible to effectively and efficiently switch the active SRM network from the SRM network 40 to the SRM network 130. Each of the FIFO memories FM_ij outputs an indication signal when it discharges all cells completely so that it becomes empty. The AND gate 31 is provide for each of the FIFO memories FM_ij as shown in FIG.14. Output signals (indication signals) of the AND gates 31 are supplied to an AND gate 32, an output signal of which is supplied, as a switching signal, to the CPU 70.
FIG.15 is a block diagram of the output module 250. As shown, the output module 250 includes a selector 251, which connects one of the SRM networks 130 and 40 to the output highway 60.
A description is given of the operation of the self-routing switching system according to the third preferred embodiment of the present invention with reference to FIG.16. When receiving a request to switch the active system from the SRM network 130 to the SRM network 40, the CPU 70 supplies the selector 29 (FIG.11) of the conversion module 220 with an instruction to connect the selector 22a to the SRM network 40 (P1). Each cell which is input to the conversion module after the instruction is generated is successively output to the SRM network 40 (P2). Then each cell is stored in the SRM network 40 from the SRM₃₁, SRM₃₂ and SRM₃₃ at the output stage thereof (P3). This is called a queuing mode. In the queuing mode, the CPU 70 prevents the SRM network 40 from outputting cells to the output module 250.
On the other hand, the SRM network 130 continues to operate and outputs cells stored therein to the output module 250 (P4). Each FIFO memory FM_ij outputs the signal indicating that there is no cell therein when it becomes such a state. When all cells in the SRM network 130 are completely output to the output module 250, the indication signal output from the AND gate 32 is turned ON (P5). Then the CPU 70 instructs the selector 251 (FIG.15) of the output module 250 to switch the connection from the SRM network 130 to the SRM network 40 (P6). Then the CPU 70 informs the SRM network 40 of the change from the queuing mode to the normal mode (P7). Thereby, the cells in the SRM network 40 are allowed to be output to the output module 250 (P8).
The present invention includes all self-routing switching networks in which cells are temporarily stored in a switching network such as the aforementioned SRM network. The present invention may be used for switching network of voice, facsimile data, computer data, and other switching data, in particular for high speed packet (cell) switching networks and high speed asynchronous transfer mode switching networks.
The present invention is not limited to the specifically described embodiments, and variations and modifications may be made without departing from the scope of the invention.
Reference signs in the claims are intended for better understanding and shall not limit the scope.

Claims

1. A self-routing switching system connected between input highways (10) and output highways (60), comprising:
input means (20, 120, 220) coupled to said input highways, for receiving a cell having transmission information from one of said input highways and for generating additive information indicative of a path through which said transmission information from said one of the input highways is supplied to one of said output highways;
first self-routing switch module network means (30, 130) for providing a plurality of paths operatively coupled between said input highways and output highways, said cell being transmitted through one of said plurality of paths indicated by said additive information; and
second self-routing switch module network means (40) for providing a plurality of paths operatively coupled between said input highways and output highways, said cell being transmitted through one of said plurality of paths indicated by said additive information, characterized in that said self-routing switching system comprises:
first selecting means (22, 29, 123, 221), provided between said input means and said first and second self-routing switch module network means, for connecting said input highways to one of said first and second self-routing switch module network means; and
second selecting means (51, 152, 251), provided between said input means and said first and second self-routing switch module network means, for connecting said output lines to one of said first and second self-routing switch module network means.

2. A self-routing switching system as claimed in claim 1, characterized in that said system further comprises detecting means (52, 152) operatively coupled to said first and second self-routing switch module network means, for detecting a state where there is no cell in said one of the first and second self-routing means selected by said first selecting means, said one of the first and second self-routing means functioning as an active network and the the other one thereof functioning as a standby network,
and that said first and second selecting means switch connections to said input and output lines from said active network to said standby network when said detecting means detects said state.

3. A self-routing switching system as claimed in claim 2, characterized by further comprising control means (70) for determining whether or not a predetermined time passes after a request to change said active network is input thereto and for controlling said first and second selecting means so as to select the connections to said input and output lines from said active network to said standby network when said control means determines that said predetermined time passes.

4. A self-routing switching system as claimed in claim 3, characterized in that said predetermined time corresponds to a time which ensures that cells in said active network are already discharged completely to said output lines through said second selecting means when said predetermined time passes.

5. A self-routing switch system as claimed in any of claims 2 to 4, characterized by further comprising:
specific cell generating means (28, 122) coupled to said input means, for generating a specific cell when a request to switch said connection is input thereto and for sending said specific cell to said active network through said first selecting means;
specific cell detecting means (52, 152) coupled to said second selecting means, for detecting said specific cell supplied from said active network; and
control means coupled to said specific cell detecting means and said first and second selecting means, for controlling said first and second selecting means so as to select said standby network instead of said active network when said specific cell detecting means detects said specific cell.

6. A self-routing switching system as claimed in claim 5, characterized by further comprising buffer means (21b, 121) coupled to said input highways, for storing cells supplied from said input highways after said request is input to said specific cell generating means.

7. A self-routing switching system as claimed in claim 6, characterized in that when said specific cell detecting means (52, 152) detects said specific cell, said cells stored in said buffer means are sent to said first selecting means.

8. A self-routing switching system as claimed in any of claims 5 to 7, characterized in that said specific cell has an identifier indicating said specific cell, and said specific cell detecting means (52, 152) comprises means for determining whether each of said cells has said identifier.

9. A self-routing switching system as claimed in any of claims 5 to 8, characterized by further comprising memory means (53) for storing said specific cell detected by said specific cell detecting means.

10. A self-routing switching system as claimed in claim 9, characterized in that said control means (70) comprises means (70) for periodically accessing said memory means and determining whether or not said specific cell detected by said specific cell detecting means is stored in said memory means.

11. A self-routing switching system as claimed in any of claims 5 to 10, characterized in that said specific cell detecting means (52, 152) generates a switching signal to be supplied to said control means when detecting said specific cell.

12. A self-routing switching system as claimed in claim 2, characterized in that said first self-routing switch module network means (130) comprises a plurality of self-routing switch modules (SRM) each buffering cells and outputting an indication signal indicating whether or not there is a cell therein, and
and that said detecting means comprises logic means (31, 32) for determining whether or not said indication signal from each of said plurality of self-routing switch modules has been output.

13. A self-routing switching system as claimed in claim 12, characterized in that said logic means comprises an AND gate (32) which receives said indication signal from each of said plurality of self-routing switch modules and outputs an AND logic result to be supplied, as said switching signal, to said control means (70).

14. A self-routing switching system as claimed in claim 12 or claim 13, characterized in that each of said plurality of self-routing switch modules (SRM) includes a plurality of buffer memories (FF) each outputting a local indication signal indicating whether or not there is a cell therein, and that said logic means comprises a first AND gate (31) which receives said local indication signal from each of said plurality of buffer memories provided in each of said plurality of self-routing switch modules and which outputs an AND logic result, and a second AND gate (32) which receives said AND logic result supplied from said first AND gate provided for each of said plurality of self-routing switch modules and which outputs an AND logic result to be supplied, as said switching signal, to said control means.

15. A self-routing switching system as claimed in claim 5, characterized in that said control means (70) controls said first selecting means (22, 29, 123) so as to select said standby network instead of said active network when said request is supplied thereto and controls said second selecting means (51, 152) so as to select said standby network when said specific cell detecting means (52, 152) detects said specific cell, and that cells from said input highways (10) are buffered in said standby network until said second selecting means selects said standby network.

16. A self-routing switching system as claimed in claim 14, characterized in that each of said buffer memories includes a first-in first-out memory (FF).

17. A self-routing switching system as claimed in any of claims 1 to 16, characterized in that each of said first and second self-routing switch module network means comprises an asynchronous transfer mode switch network.